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Continuous collection method of particle component in aqueous solution and apparatus therefor

a technology of continuous particle component and aqueous solution, which is applied in the direction of solvent extraction, separation process, filtration treatment, etc., can solve the problems of increased running cost, increased maintenance cost, and difficult handling, and achieves more stable operation, finer grain, and stable operation

Inactive Publication Date: 2010-04-01
JAPAN ATOMIC ENERGY AGENCY INDEPENDANT ADMINISTRATIVE CORP
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  • Summary
  • Abstract
  • Description
  • Claims
  • Application Information

AI Technical Summary

Benefits of technology

[0005]On the other hand, emulsion flow technology developed recently can establish the emulsion state of two liquid mixtures only by liquid supply, and hence, does not require external forces differently from conventional liquid-liquid apparatus (JP 2008-289975 A). Thus, all the above-mentioned disadvantageous features associated with the conventional apparatus can be resolved. Emersion flow technology is such an innovative method that enables liquid-liquid extraction (solvent extraction) in a simplified manner similar to column-type liquid-to-solid extraction method which uses solid materials such as resin to be filled into the column. In other words, the extraction apparatus using emulsion flow has also advantageous features in the column-type liquid-solid extraction apparatus (being easy to handle and low running cost) in addition to the advantageous features in the conventional solvent extraction apparatus, such as mixer-settler extractor (large extraction volume and rapid extraction process). As large extraction capacity and rapid extraction process cannot be realized by the column-type liquid-solid extraction apparatus, and easiness to handle and low running cost cannot be realized by the conventional solvent extraction apparatus, it is very significant to enable to establish the co-existence of those advantageous features.
[0009]A further object of the present invention is to provide a counter-current type emulsion flow continuous liquid-liquid extraction apparatus allowing to: 1) obtain the extraction rate (extractability) over 90% by generating high quality emulsion flow; 2) facilitate scale-up of the apparatus by maintaining stable emulsion flow in the wide region; 3) prevent the particle component in the aqueous solution from plugging holes in the head part.
[0014]It will be appreciated that the apparatus according to the present invention, in comparison with the conventional apparatus based on the continuous centrifugal separation method, may provide larger processing capacity and reduced levels of running cost, initial cost and maintenance cost as well as the size of the apparatus itself is compact. Thus, the apparatus according to the present invention is expected to be used in plants in various industrial fields. In addition, it will be appreciated that the method according to the present invention may provide such a significant effect not found in the conventional methods that the dissolved component as well as the particle component can be simultaneously collected, as necessary, being combined with the liquid-liquid extraction method.
[0015]Moreover, it will be appreciated that high quality and stable characteristic in the emulsion can be attained; the target component can be extracted with higher extractability, and also that the scale-up of the apparatus can be facilitated, all of which cannot be attained by the emulsion flow apparatus based on the single current method. In addition, by adopting the counter-current method, the plugging problem in the head part due to the particle component such as suspension materials, which is recognized as the critical weak point of the emulsion flow apparatus based on the single current method, is solved.

Problems solved by technology

The above mentioned apparatuses, however, have the common principle for mixing two liquid phases by applying mechanical external forces (such as stirring and vibrating) continuously or intermittently, which may lead to such disadvantageous aspects as being not easy to handle, increased running cost, increased maintenance cost, increased apparatus manufacturing cost (initial cost), uncertain safety features.
More specifically, they include: 1) large energy load required to generate mechanical external forces; 2) load and stress at the driving parts for generating mechanical external forces; 3) long adjusting work required to prepare and setup the operation of apparatus; 4) risk of ignition due to friction or static electricity at the driving parts; 5) high strength and high price materials required to manufacture the driving parts; 6) ambient noises in connection with stirring, vibrating and high-speed rotating operations; and 7) uncertainty in ensuring safety during earthquake.
Although emulsion flow technology is an innovative method as described above, it has some unresolved problems.
At first, in the conventional single current method, it is difficult to generate fine-grained and high quality emulsion flow, and it is not easy to obtain the extraction rate (extractability) over 90% because some amount of non-uniformity occurs.
In addition, in the single current method, as it is difficult to maintain stable emulsion flow in the wide region, there is a problem in scale-up of the apparatus.
This plugging problem has been a major challenge in the improvement of the emulation flow because the particle component may typically coexist as suspension materials in the aqueous solution.

Method used

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  • Continuous collection method of particle component in aqueous solution and apparatus therefor
  • Continuous collection method of particle component in aqueous solution and apparatus therefor
  • Continuous collection method of particle component in aqueous solution and apparatus therefor

Examples

Experimental program
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Effect test

embodiment 1

Experiment for Collecting Particle Component in Aqueous Solution by Small-sized Apparatus

[0047]Refer to FIG. 3A and FIG. 3B. Using a small-sized emulsion flow apparatus 10a (with the apparatus volume=3 litters and the apparatus weight=2 kg), an experiment for collecting aluminum oxide Al2O3 particles was carried out. More specifically, 20 litters of aqueous nitric acid solution (pH 2) including aluminum oxide Al2O3 particles (with particle diameter between 20 μm and 25 μm) by 0.02 M were prepared and an experiment for collecting the particle component was carried out by using a small-sized emulsion flow apparatus provided with 1 litter of isooctane. FIG. 3A shows a photo picture of the small-sized emulsion flow apparatus used in the experiment. The first head part 11 used in the apparatus has such a structure that the side wall of the hollow cylinder with its one end being closed, being made of polypropylene, is and being provided with 10 holes having 1 mm diameter. The second head ...

embodiment 2

Experiment for Collecting Particle Component in Aqueous Solution by Intermediate-sized Apparatus

[0049]Refer to FIG. 4A. FIG. 4A shows an intermediate-sized emulsion flow apparatus. The term of “Intermediate-sized” apparatus means an apparatus having an apparatus volume three times larger than the apparatus volume used in Embodiment 1. In this experiment, the intermediate-sized emulsion flow apparatus shown in FIG. 4A (with the apparatus volume=9 litters and the apparatus weight=4 kg) was used. The first head part 11 used in the apparatus has such a structure that the side wall of the hollow cylinder with its one end being closed, being made of polypropylene, and being provided with 6 holes having 4.8 mm diameter. The second head part 12 has such a structure that a sintered glass plate having pores with 40 μm diameter bonded onto the end of the hollow cylinder as described above. In order to avoid emulsion mixed phase and supply clean solvent phase, the upper phase separation part 14...

embodiment 3

Experiment for Collecting Simultaneously Particle Component and Dissolved Component in Aqueous Solution

[0053]Dissolved metallic ion and suspended particle component can be selectively and simultaneously collected by adding an extraction agent relevant to the metal ion to such a solvent phase as isooctane; while, in Embodiment 1 and Embodiment 2, pure isooctane is used. In Embodiment 3, an experiment was carried out by using the above described intermediate-sized emulsion flow apparatus provided with 2 litters of isooctane including bis(2-ethylhexyl) phosphoric acid (DEHPA) as the extraction agent by 1×10−3 M and with 200 litters of aqueous nitric acid solution (pH 2) including aluminum oxide Al2O3 particles as the particle component by 0.02 M and ytterbium Yb (trivalent ion) as the dissolved component by 6×10−6 M. As the experimental result, almost 100% of aluminum oxide Al2O3 particles as the particle component and about 98% of ytterbium Yb as the dissolved component could be separ...

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Abstract

The particle components may be collected by using a phenomenon that the particle components in the aqueous phase aggregate at the liquid-to-liquid interface. Both of the particle components and the dissolved components in the aqueous phase may be simultaneously collected if combined with liquid-liquid extraction phenomenon that the dissolved components in the aqueous phase are collected into the solvent phase through the liquid-to-liquid interface. The aggregation phenomenon of the particle components at the liquid-to-liquid interface may be promoted by using an emulsion flow method, a method of applying mechanical external forces (such as stirring and vibrating) or another method combining both the above-mentioned methods.

Description

BACKGROUND OF THE INVENTION[0001]The present invention relates to a method for collecting continuously particle component in the aqueous solution without using filters and / or centrifuge separators. The method utilizes a phenomenon that particle component in the aqueous solution aggregates at the liquid-to-liquid interface between the aqueous solution (aqueous phase) containing the particle component as the target component and the solvent (solvent phase) having hydrophobic nature and not mixing with water.[0002]Liquid-liquid extraction method (solvent extraction method), by which the target component included in the aqueous solution may be extracted into the solvent (such as organic solvent) that contains extraction agents (extractants) having hydrophobic nature and does not mix with water, is widely used in various industrial fields such as metal refinement, nuclear fuel reprocessing, removal of harmful ingredients in the waste water, recycling by separation and recovering of comme...

Claims

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Application Information

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IPC IPC(8): B01D15/32B01D15/08
CPCB01D11/0434B01D11/0438C02F1/54C02F1/26C02F1/001
Inventor NAGANAWA, HIROCHIKAYANASE, NOBUYUKINAGANO, TETSUSHI
Owner JAPAN ATOMIC ENERGY AGENCY INDEPENDANT ADMINISTRATIVE CORP
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